BambuStudio/libslic3r/Geometry/Circle.cpp

#include "Circle.hpp"

#include "../Polygon.hpp"

#include <numeric>
#include <random>
#include <boost/log/trivial.hpp>

namespace Slic3r { namespace Geometry {

Point circle_center_taubin_newton(const Points::const_iterator& input_begin, const Points::const_iterator& input_end, size_t cycles)
{
    Vec2ds tmp;
    tmp.reserve(std::distance(input_begin, input_end));
    std::transform(input_begin, input_end, std::back_inserter(tmp), [] (const Point& in) { return unscale(in); } );
    Vec2d center = circle_center_taubin_newton(tmp.cbegin(), tmp.end(), cycles);
	return Point::new_scale(center.x(), center.y());
}

/// Adapted from work in "Circular and Linear Regression: Fitting circles and lines by least squares", pg 126
/// Returns a point corresponding to the center of a circle for which all of the points from input_begin to input_end
/// lie on.
Vec2d circle_center_taubin_newton(const Vec2ds::const_iterator& input_begin, const Vec2ds::const_iterator& input_end, size_t cycles)
{
    // calculate the centroid of the data set
    const Vec2d sum = std::accumulate(input_begin, input_end, Vec2d(0,0));
    const size_t n = std::distance(input_begin, input_end);
    const double n_flt = static_cast<double>(n);
    const Vec2d centroid { sum / n_flt };

    // Compute the normalized moments of the data set.
    double Mxx = 0, Myy = 0, Mxy = 0, Mxz = 0, Myz = 0, Mzz = 0;
    for (auto it = input_begin; it < input_end; ++it) {
        // center/normalize the data.
        double Xi {it->x() - centroid.x()};
        double Yi {it->y() - centroid.y()};
        double Zi {Xi*Xi + Yi*Yi};
        Mxy += (Xi*Yi);
        Mxx += (Xi*Xi);
        Myy += (Yi*Yi);
        Mxz += (Xi*Zi);
        Myz += (Yi*Zi);
        Mzz += (Zi*Zi);
    }

    // divide by number of points to get the moments
    Mxx /= n_flt;
    Myy /= n_flt;
    Mxy /= n_flt;
    Mxz /= n_flt;
    Myz /= n_flt;
    Mzz /= n_flt;

    // Compute the coefficients of the characteristic polynomial for the circle
    // eq 5.60
    const double Mz {Mxx + Myy}; // xx + yy = z
    const double Cov_xy {Mxx*Myy - Mxy*Mxy}; // this shows up a couple times so cache it here.
    const double C3 {4.0*Mz};
    const double C2 {-3.0*(Mz*Mz) - Mzz};
    const double C1 {Mz*(Mzz - (Mz*Mz)) + 4.0*Mz*Cov_xy - (Mxz*Mxz) - (Myz*Myz)};
    const double C0 {(Mxz*Mxz)*Myy + (Myz*Myz)*Mxx - 2.0*Mxz*Myz*Mxy - Cov_xy*(Mzz - (Mz*Mz))};

    const double C22 = {C2 + C2};
    const double C33 = {C3 + C3 + C3};

    // solve the characteristic polynomial with Newton's method.
    double xnew = 0.0;
    double ynew = 1e20;

    for (size_t i = 0; i < cycles; ++i) {
        const double yold {ynew};
        ynew = C0 + xnew * (C1 + xnew*(C2 + xnew * C3));
        if (std::abs(ynew) > std::abs(yold)) {
			BOOST_LOG_TRIVIAL(error) << "Geometry: Fit is going in the wrong direction.\n";
            return Vec2d(std::nan(""), std::nan(""));
        }
        const double Dy {C1 + xnew*(C22 + xnew*C33)};

        const double xold {xnew};
        xnew = xold - (ynew / Dy);

        if (std::abs((xnew-xold) / xnew) < 1e-12) i = cycles; // converged, we're done here

        if (xnew < 0) {
            // reset, we went negative
            xnew = 0.0;
        }
    }
    
    // compute the determinant and the circle's parameters now that we've solved.
    double DET = xnew*xnew - xnew*Mz + Cov_xy;

    Vec2d center(Mxz * (Myy - xnew) - Myz * Mxy, Myz * (Mxx - xnew) - Mxz*Mxy);
    center /= (DET * 2.);
    return center + centroid;
}

Circled circle_taubin_newton(const Vec2ds& input, size_t cycles)
{
    Circled out;
    if (input.size() < 3) {
        out = Circled::make_invalid();
    } else {
        out.center = circle_center_taubin_newton(input, cycles);
        out.radius = std::accumulate(input.begin(), input.end(), 0., [&out](double acc, const Vec2d& pt) { return (pt - out.center).norm() + acc; });
        out.radius /= double(input.size());
    }
    return out;
}

Circled circle_ransac(const Vec2ds &input, size_t iterations, double *min_error)
{
    if (input.size() < 3)
        return Circled::make_invalid();

    std::mt19937       rng;
    std::vector<Vec2d> samples;
    Circled            circle_best = Circled::make_invalid();
    double             err_min     = std::numeric_limits<double>::max();
    for (size_t iter = 0; iter < iterations; ++iter) {
        samples.clear();
        std::sample(input.begin(), input.end(), std::back_inserter(samples), 3, rng);
        Circled c;
        c.center = Geometry::circle_center(samples[0], samples[1], samples[2], EPSILON);
        c.radius = std::accumulate(input.begin(), input.end(), 0., [&c](double acc, const Vec2d &pt) { return (pt - c.center).norm() + acc; });
        c.radius /= double(input.size());
        double err = 0;
        for (const Vec2d &pt : input)
            err = std::max(err, std::abs((pt - c.center).norm() - c.radius));
        if (err < err_min) {
            err_min     = err;
            circle_best = c;
        }
    }
    if (min_error)
        *min_error = err_min;
    return circle_best;
}

} } // namespace Slic3r::Geometry
初始化 2024-12-20 06:44:50 +00:00			`#include "Circle.hpp"`

			`#include "../Polygon.hpp"`

			`#include <numeric>`
			`#include <random>`
			`#include <boost/log/trivial.hpp>`

			`namespace Slic3r { namespace Geometry {`

			`Point circle_center_taubin_newton(const Points::const_iterator& input_begin, const Points::const_iterator& input_end, size_t cycles)`
			`{`
			`Vec2ds tmp;`
			`tmp.reserve(std::distance(input_begin, input_end));`
			`std::transform(input_begin, input_end, std::back_inserter(tmp), [] (const Point& in) { return unscale(in); } );`
			`Vec2d center = circle_center_taubin_newton(tmp.cbegin(), tmp.end(), cycles);`
			`return Point::new_scale(center.x(), center.y());`
			`}`

			`/// Adapted from work in "Circular and Linear Regression: Fitting circles and lines by least squares", pg 126`
			`/// Returns a point corresponding to the center of a circle for which all of the points from input_begin to input_end`
			`/// lie on.`
			`Vec2d circle_center_taubin_newton(const Vec2ds::const_iterator& input_begin, const Vec2ds::const_iterator& input_end, size_t cycles)`
			`{`
			`// calculate the centroid of the data set`
			`const Vec2d sum = std::accumulate(input_begin, input_end, Vec2d(0,0));`
			`const size_t n = std::distance(input_begin, input_end);`
			`const double n_flt = static_cast<double>(n);`
			`const Vec2d centroid { sum / n_flt };`

			`// Compute the normalized moments of the data set.`
			`double Mxx = 0, Myy = 0, Mxy = 0, Mxz = 0, Myz = 0, Mzz = 0;`
			`for (auto it = input_begin; it < input_end; ++it) {`
			`// center/normalize the data.`
			`double Xi {it->x() - centroid.x()};`
			`double Yi {it->y() - centroid.y()};`
			`double Zi {XiXi + YiYi};`
			`Mxy += (Xi*Yi);`
			`Mxx += (Xi*Xi);`
			`Myy += (Yi*Yi);`
			`Mxz += (Xi*Zi);`
			`Myz += (Yi*Zi);`
			`Mzz += (Zi*Zi);`
			`}`

			`// divide by number of points to get the moments`
			`Mxx /= n_flt;`
			`Myy /= n_flt;`
			`Mxy /= n_flt;`
			`Mxz /= n_flt;`
			`Myz /= n_flt;`
			`Mzz /= n_flt;`

			`// Compute the coefficients of the characteristic polynomial for the circle`
			`// eq 5.60`
			`const double Mz {Mxx + Myy}; // xx + yy = z`
			`const double Cov_xy {MxxMyy - MxyMxy}; // this shows up a couple times so cache it here.`
			`const double C3 {4.0*Mz};`
			`const double C2 {-3.0(MzMz) - Mzz};`
			`const double C1 {Mz(Mzz - (MzMz)) + 4.0MzCov_xy - (MxzMxz) - (MyzMyz)};`
			`const double C0 {(MxzMxz)Myy + (MyzMyz)Mxx - 2.0MxzMyzMxy - Cov_xy(Mzz - (Mz*Mz))};`

			`const double C22 = {C2 + C2};`
			`const double C33 = {C3 + C3 + C3};`

			`// solve the characteristic polynomial with Newton's method.`
			`double xnew = 0.0;`
			`double ynew = 1e20;`

			`for (size_t i = 0; i < cycles; ++i) {`
			`const double yold {ynew};`
			`ynew = C0 + xnew * (C1 + xnew(C2 + xnew C3));`
			`if (std::abs(ynew) > std::abs(yold)) {`
			`BOOST_LOG_TRIVIAL(error) << "Geometry: Fit is going in the wrong direction.\n";`
			`return Vec2d(std::nan(""), std::nan(""));`
			`}`
			`const double Dy {C1 + xnew(C22 + xnewC33)};`

			`const double xold {xnew};`
			`xnew = xold - (ynew / Dy);`

			`if (std::abs((xnew-xold) / xnew) < 1e-12) i = cycles; // converged, we're done here`

			`if (xnew < 0) {`
			`// reset, we went negative`
			`xnew = 0.0;`
			`}`
			`}`

			`// compute the determinant and the circle's parameters now that we've solved.`
			`double DET = xnewxnew - xnewMz + Cov_xy;`

			`Vec2d center(Mxz * (Myy - xnew) - Myz * Mxy, Myz * (Mxx - xnew) - Mxz*Mxy);`
			`center /= (DET * 2.);`
			`return center + centroid;`
			`}`

			`Circled circle_taubin_newton(const Vec2ds& input, size_t cycles)`
			`{`
			`Circled out;`
			`if (input.size() < 3) {`
			`out = Circled::make_invalid();`
			`} else {`
			`out.center = circle_center_taubin_newton(input, cycles);`
			`out.radius = std::accumulate(input.begin(), input.end(), 0., [&out](double acc, const Vec2d& pt) { return (pt - out.center).norm() + acc; });`
			`out.radius /= double(input.size());`
			`}`
			`return out;`
			`}`

			`Circled circle_ransac(const Vec2ds &input, size_t iterations, double *min_error)`
			`{`
			`if (input.size() < 3)`
			`return Circled::make_invalid();`

			`std::mt19937 rng;`
			`std::vector<Vec2d> samples;`
			`Circled circle_best = Circled::make_invalid();`
			`double err_min = std::numeric_limits<double>::max();`
			`for (size_t iter = 0; iter < iterations; ++iter) {`
			`samples.clear();`
			`std::sample(input.begin(), input.end(), std::back_inserter(samples), 3, rng);`
			`Circled c;`
			`c.center = Geometry::circle_center(samples[0], samples[1], samples[2], EPSILON);`
			`c.radius = std::accumulate(input.begin(), input.end(), 0., [&c](double acc, const Vec2d &pt) { return (pt - c.center).norm() + acc; });`
			`c.radius /= double(input.size());`
			`double err = 0;`
			`for (const Vec2d &pt : input)`
			`err = std::max(err, std::abs((pt - c.center).norm() - c.radius));`
			`if (err < err_min) {`
			`err_min = err;`
			`circle_best = c;`
			`}`
			`}`
			`if (min_error)`
			`*min_error = err_min;`
			`return circle_best;`
			`}`

			`} } // namespace Slic3r::Geometry`